Advances in heavy alkaline earth chemistry provide insight into complexation of weakly polarizing Ra 2+ , Ba 2+ , and Sr 2+ cations.
J Connor GilhulaLei XuFrankie D WhiteSara L AdelmanKelly E AldrichEnrique R BatistaDavid DanZachary R JonesStosh Anthony KozimorHarris E MasonRachel L MeyerNikki A ThielePing YangMingbin YuanPublished in: Science advances (2024)
Numerous technologies-with catalytic, therapeutic, and diagnostic applications-would benefit from improved chelation strategies for heavy alkaline earth elements: Ra 2+ , Ba 2+ , and Sr 2+ . Unfortunately, chelating these metals is challenging because of their large size and weak polarizing power. We found 18-crown-6-tetracarboxylic acid ( H 4 COCO ) bound Ra 2+ , Ba 2+ , and Sr 2+ to form M(H x COCO) x -2 . Upon isolating radioactive 223 Ra from its parent radionuclides ( 227 Ac and 227 Th), 223 Ra 2+ reacted with the fully deprotonated COCO 4- chelator to generate Ra(COCO) 2- ( aq ) (log K Ra(COCO)2- = 5.97 ± 0.01), a rare example of a molecular radium complex. Comparative analyses with Sr 2+ and Ba 2+ congeners informed on what attributes engendered success in heavy alkaline earth complexation. Chelators with high negative charge [-4 for Ra(COCO) 2- ( aq ) ] and many donor atoms [≥11 in Ra(COCO) 2- ( aq ) ] provided a framework for stable complex formation. These conditions achieved steric saturation and overcame the weak polarization powers associated with these large dicationic metals.